Studies on the effects of vinblastine and colchicine on Trypanosoma gambiense

Vinblastine and colchicine induce the anucleate form of Trypanosoma gambiense. Light microscopic studies indicated that the anucleate form was not always produced as a result of inhibition of nuclear duplication, but was formed as a result of delay or inhibition of separation of the two nuclei after completion of nuclear division. Studies showed that vinblastine and colchicine caused disorder in arrangement of axonemal microtubules of the extracellular flagella and increased formation of both protofilaments and the axoneme composed of protofilaments in trypanosomes. Moreover, treatment with colchicine resulted in disintegration of previously existing pellicular microtubules and formation of cytoplasmic projections that appeared as protrusions from a small part of the surface membrane.     

The relationship between the disassembly of microtubules during G1 and the enhancement of DNA synthesis by colchicine in mouse fibroblasts stimulated with peptide growth hormones

By immunofluorescent staining to visualize the cytoplasmic microtubular cytoskeleton in mouse fibroblasts we have ascertained that after a relatively short exposure of cells to colchicine, microtubules remain disassembled for a prolonged period of time after cells are transferred to a colchicine-free medium. In contrast to the persisting effects of colchicine, a brief exposure of cells to nocodazole first induces the expected disruption of microtubules followed by regeneration of the cytoskeleton within a few hours after removal of extracellular drug. These results shed light on our previous finding that quiescent mouse fibroblasts first treated with colchicine and then transferred to colchicine-free medium exhibit an enhanced proliferative response to EGF and insulin, whereas cells treated in a similar manner with nocodazole show no enhancement of DNA synthesis stimulated by peptide growth hormones. We conclude that cytoplasmic microtubules must remain disaggregated during the prereplicative G1 period in order for cells to exhibit the enhancing effects of the microtubule-disrupting drugs on DNA synthesis.     

Differentiation of epidermal cells in the regenerating planarian Dugesia japonica

Distribution of the cytoplasmic components in planarian epidermal cells is highly polarized, just as in vertebrate epithelia. Differentiating epidermal cells of the planarian Dugesia japonica Ichikawa et Kawakatsu were found to have relatively conspicuous accumulations of microtubules in their apical cytoplasm. When colchicine, a microtubule-disrupting drug, was applied to regenerating worms, it reversibly disorganized the polarity of differentiating epidermal cells. Cytochalasin B, which depolymerizes actin filaments, had no significant effect on the polarization, however. Tubulin could be localized by immunocytochemistry in the cytoplasm of differentiating epidermal cells; this reaction was inhibited by treatment with colchicine for 20 h. These observations indicate that microtubules play a role in establishing polarity during cell differentiation.     

Abnormal spore cleavage: Abnormal spores of Allomyces macrogynus

In the aquatic phycomycete Allomyces macrogynus abnormal spore cleavage takes place in the presence of colchicine or benomyl resulting in multinucleate–multiflagellate spores due to failure in the formation of cytoplasmic microtubules after the induction of zoosporogenesis. The 27 cytoplasmic microtubules which normally surround the nucleus and nuclear cap of the mature spore are not formed in the presence of colchicine or benomyl. At high concentrations of colchicine (4–8 mg/ml) the spores do not have a flagellum. Colchicine or benomyl inhibit microtubule formation during zoosporogenesis and also appear to perturb the mobilization of the gamma bodies which are believed to be the source of the vesicles which form the axonemal membrane and cleavage furrows. These observations are discussed in relation to the hypothesis of Heath that cytoplasmic microtubules formed during zoosporogenesis determine cytoplasmic domains which will delimit the spore initials at cleavage. The observations presented here appear to confirm this hypothesis.     

The stabilization of microtubules in isolated spindles by tubulin-colchicine complex

We have analyzed the effect of colchicine and tubulin dimer-colchicine complex (T-C) on microtubule assembly in mitotic spindles. Cold- and calcium-labile mitotic spindles were isolated from embryos of the sea urchin Lytechinus variegatus employing EGTA/glycerol stabilization buffers. Polarization microscopy and measurements of spindle birefringent retardation (BR) were used to record the kinetics of microtubule assembly-disassembly in single spindles. When isolated spindles were perfused out of glycerol stabilizing buffer into a standard in vitro microtubule reassembly buffer (0.1 M Pipes, pH 6.8, 1 mM EGTA, 0.5 mM MgCl2, and 0.5 mM GTP) lacking glycerol, spindle BR decreased with a half-time of 120 s. Colchicine at 1 mM in this buffer had no effect on the rate of spindle microtubule disassembly. Inclusion of 20 microM tubulin or microtubule protein, purified from porcine brain, in this buffer resulted in an augmentation of spindle BR. Interestingly, in the presence of 20 microM T-C, spindle BR did not increase, but was reversibly stabilized; subsequent perfusion with reassembly buffer without T-C resulted in depolymerization. This behavior is striking in contrast to the rapid depolymerization of spindle microtubules induced by colchicine and T-C in vivo. These results support the current view that colchicine does not directly promote microtubule depolymerization. Rather, it is T-C complex that alters microtubule assembly, by reversibly binding to microtubules and inhibiting elongation. In vivo, colchicine can induce depolymerization of nonkinetochore spindle microtubules within 20 s. In vitro, colchicine blocks further microtubule assembly, but does not induce rapid disassembly.(ABSTRACT TRUNCATED AT 250 WORDS)     

The role of spindle microtubules in the timing of the cell cycle in echinoderm eggs

Spindle microtubules play an important role in the mechanisms that control the timing of cell cycle events in the eggs of the sea urchins L. variegatus and L. pictus. However, recent work which used colchicine to block microtubule assembly in the eggs of two other echinoderms, S. purpuratus and D. excentricus, has raised serious questions about the generality of this role for spindle microtubules. Thus, we have systematically examined the role of spindle microtubules in the timing of the cell cycle in the fertilized eggs of these latter species. We treated eggs of both species with 5-10 microM Colcemid for several minutes starting 30 min after fertilization to completely prevent spindle microtubule assembly for several h. We used Colcemid, instead of colchicine, because it is effective at lower doses and, at these doses, shows no detectable toxic side effects. We compared for control and treated eggs the time course of nuclear envelope breakdown/reformation and DNA synthesis. We found for both species that the eggs continue to cycle without spindle microtubules; mitosis is up to twice the normal duration while interphase remains essentially unaffected. To test for the possible toxic side effects of the 1-2 mM colchicine used earlier on S. purpuratus and D. excentricus, we treated eggs of these two species, and also those of L. variegatus, with 1 mM lumi-colchicine. This photo-inactivated form of colchicine, which does not bind to tubulin, substantially prolongs mitosis and, to a lesser extent, interphase. Thus, the results of the earlier work are most easily explained by the combination of specific and nonspecific effects of the 1-2 mM colchicine used. Our present results indicate that the importance of spindle microtubules in the mechanisms that control the timing of the mitosis portion of the cell cycle is a general phenomenon.     

Effect of colchicine, vinblastine, and cytochalasin B on cell surface anionic sites of Tritrichomonas foetus

Drugs that interact with microtubules (colchicine and vinblastine) and microfilaments (cytochalasin B) partially inhibited cell growth and motility of Tritrichomonas foetus. Parasites incubated with these substances became rounded and cell division was blocked. Neither colchicine nor vinblastine disrupted the microtubules that form the peltar-axostylar system. Any one of these drugs interfered with the net negative surface charge of T. foetus as evaluated by determination of the cellular electrophoretic mobility (EPM). The decrease in the EPM of cytochalasin B-treated cells was caused by dimethylsulfoxide, which was used as solvent. Untreated cells as well as cytochalasin B-treated cells showed a uniform distribution of anionic sites on the plasma membrane as seen with cationized ferritin particles. In cells treated with colchicine or vinblastine the anionic sites were distributed in patches. These results are discussed in terms of participation of labile cytoplasmic microtubules and microfilaments in the control of the distribution of anionic site-containing macromolecules located on the cell surface of T. foetus.     

Differential effects of antimitotic agents on the stability and behavior of cytoplasmic and ciliary microtubules

Summary When sea urchin gastrulae are treated with colchicine or hydrostatic pressure the cytoplasmic microtubules disappear, but the ciliary microtubules which make up the ciliary axoneme (9+2) remain. With calcium-free sea water the cytoplasmic microtubules are reduced in number yet the 9+2 complex in the cilia is unaffected. Furthermore during the administration of any of these agents the cilia continue to beat so that functionally as well as morphologically the ciliary microtubules are normal even though the cytoplasmic microtubules are broken down and their presumed function in development is interrupted.Available evidence indicates that these two types of microtubules appear to be made up of similar subunits. Since there are morphological connections between the microtubules of the ciliary axoneme, and since the ciliary microtubules appear to stain more intensely than the cytoplasmic microtubules, we conclude that the ciliary microtubules are stabilized either by the addition of material or through interactions between adjacent tubules or both.Supported by Grant #5T 1-GM-707 from the National Institutes of Health to ProfessorKeith R.Porter.     

Microtubules and cyclic amp in human leukocytes: on the order of things

We have shown previously that the β-adrenergic agonist isoproterenol (2μM) and the phosphodiesterase inhibitor isobutylmethylxanthine (1 mM) produce a much greater increase in cyclic AMP in human leukocytes that have been pretreated with colchicine (or with other agents that affect microtubule assembly) than in control leukocytes. The effects of colchicines were both time- and dose-dependant. These and other data suggested that the generation of cyclic AMP is normally restricted by an intact system of cytoplasmic microtubules. If so, then the same time and dose dependencies might apply to other colchicines-induced changes in leukocyte function. We have now assayed the distribution of concanavalin A (Con A)-receptor complexes on the leukocyte membrane, taking into account that leukocytes competent to assemble microtubules show a uniform distribution of surface- bound Con A whereas microtubule-deficient cells accumulate Con A in surface caps. We have found that the effect of colchicine on capping is also both time- and dose dependent, and that the dose-response relationships conform to those required to increase cyclic AMP levels. These findings provide further evidence that both colchicine-induced Con-A capping and colchicine- induced cyclic AMP generation depend upon the relaxation of constraints normally imposed by cytoplasmic microtubules upon the plasma membrane, which limit, respectively, lateral mobility of the lectin-receptor complexes, and expression of hormone-sensitive adenylate cyclase. Moreover, colchicine-induced Con-A cap formation is not affected even by very large changes in leukocyte cyclic AMP levels. Thus, elevated cyclic AMP levels do not appear to promote the dissolution of microtubules; rather, the dissolution of microtubules permits the generation of increased amounts of cyclic AMP.     

Immunofluorescence demonstration of tubulin and actin in estrogen-induced rat prolactinoma cells in vitro : Alteration of their distribution after bromocriptine, colchicine and cytochalasin B treatments

Cultured cells in vitro from estrogen-induced rat prolactin-secreting adenomas (prolactinomas) were examined by indirect immunofluorescence microscopy for the distribution of cytoskeletal proteins and alterations of cytoskeleton after treatment with bromocriptine, colchicine and cytochalasin B (CB). After 8 days in culture, prolactinoma cells were well expanded and developed cytoplasmic processes were seen. The cytoplasmic microtubules were observed as fine reticular networks radiating from perinuclear portions toward the cell periphery when decorated with an antibody against tubulin. On the other hand, the actin filaments showed diffuse and spotty distribution when detected with an anti-actin antibody. Contaminated fibroblasts showed a reticular distribution of microtubules and a parallel array of actin cables which corresponds to "stress fibers" throughout the cytoplasm. After treatment with bromocriptine, the reticular distribution of microtubules in prolactinoma cells changed into a coarse and sparse pattern, which was identical with the changes in the distribution of tubulin after treatment with colchicine. On the other hand, distribution of actin was not affected by bromocriptine. Bromocriptine treatment did not alter the distribution of microtubules and actin filaments in fibroblasts, whereas colchicine changed the distribution of microtubules in both prolactinoma cells and fibroblasts. CB treatment changed the localization of actin filaments in both kinds of cells. These in vitro studies indicated bromocriptine would selectively affect the cytoplasmic microtubular system of prolactinoma cells.     

Effect of Colchicine,Vinblastine, and Cytochalasin B on Cell Surface Anionic Sites of Tritrichomonas foetus1

ABSTRACT. Drugs that interact with microtubules (colchicine and vinblastine) and microfilaments (cytochalasin B) partially inhibited cell growth and motility of Tritrichomonas foetus. Parasites incubated with these substances became rounded and cell division was blocked. Neither colchicine nor vinblastine disrupted the microtubules that form the peltar-axostylar system. Any one of these drugs interfered with the net negative surface charge of T. foetus as evaluated by determination of the cellular electrophoretic mobility (EPM). The decrease in the EPM of cytochalasin B-treated cells was caused by dimethylsulfoxide, which was used as solvent. Untreated cells as well as cytochalasin B-treated cells showed a uniform distribution of anionic sites on the plasma membrane as seen with cationized ferritin particles. In cells treated with colchicine or vinblastine the anionic sites were distributed in patches. These results are discussed in terms of participation of labile cytoplasmic microtubules and microfilaments in the control of the distribution of anionic sitecontaining macromolecules located on the cell surface of T. foetus.     

A new model of reticulopodial motility and shape: evidence for a microtubule-based motor and an actin skeleton

Cytoskeletal inhibitors were used as probes to test the involvement of microtubules and actin microfilaments in the development, motility, and shape maintenance of the pseudopodial networks (i e, reticulopodia) of the foraminifers Allogromia sp strain NF and Allogromia laticollaris. Agents that disassemble cytoplasmic microtubules (cold, colchicine, and nocodazole) arrest all movement but have variable effects on reticulopodial shape. Electron microscopy reveals a granulofibrillar matrix but few, if any, microtubules in these motility-arrested reticulopods. Allogromiids treated with cytochalasin B or D lose substrate adhesion and undergo dramatic changes in shape and motile behavior, highlighted by the coalescence of reticulopodial cytoplasm into irregularly shaped bodies with chaotic motility. Serial semithick sections of such preparations, viewed by high-voltage electron microscopy, document a striking rearrangement of microtubules within these cytochalasin-induced bodies. All aspects of cytochalasin-altered motility are completely inhibited by colchicine. Actin is present in reticulopodia, as determined by staining with rhodamine-phalloidin; this staining is not observed in cytochalasin-treated organisms. These data provide compelling evidence that microtubules are required for reticulopodial motility. An actin-based cytoskeleton is thought to play a role in maintaining shape, mediating pseudopod/substrate adhesion, and coordinating the various microtubule-dependent processes.     

The Role of Microtubules in Macronuclear Division of Blepharisma*

SYNOPSIS. The macronucleus of the heterotrich ciliate Blepharisma undergoes a spectacular change in form in preparation for its division. The elongation phase of this cycle has been examined by light and electron microscopy. Coincident with elongation, microtubules appear closely applied to the outer surface of the macronucleus and parallel to the direction of elongation, and disappear as elongation is completed. It is demonstrated that the antimitotic drugs colchicine and podophyllotoxin reversibly block macronuclear elongation but do not entirely inhibit morphogenetic events including cell division. The failure of colchicine-treated macronuclei to begin or continue elongation is correlated with the prevention of formation, disruption, and/or disorientation of the extranuclear microtubules.     

Time and cell cycle dependent formation of heterogeneous tubulin arrays induced by colchicine in Triticum aestivum root meristem

We have investigated the appearance and reorganization of tubulin-containing arrays induced by colchicine in the root meristem of wheat Triticum aestivum, using immunostaining and electron microscopy. Colchicine caused depolymerization of microtubules and formation of tubulin cortical strands composed of filamentous material only in C-mitotic cells. After prolonged exposure to the drug, both interphase and C-mitotic cells acquired needle-type bundles, arranged as different crystalloids and/or macrotubules. The unmodified tyrosinated form of alpha-tubulin was detected within microtubules in control cells, but was not found within cortical strands. It was identified, however, within needle-type bundles. The modified acetylated form of alpha-tubulin, which was absent in control cells, was detected within needle-type bundles. Thus, cortical strands were transitory arrays, transformed into needle-type bundles during prolonged exposure to colchicine. Cortical strands appeared in a cell cycle-dependent manner, whereas needle-type bundles were cell cycle stable arrays. The diverse morphological organization, intracellular distribution and stability of tubulin-containing arrays may be associated with heterogeneity of alpha-tubulin isoforms. We assume that non-microtubular arrays substitute for microtubules in conditions where normal tubulin polymerization is inhibited.     

Actin cytoskeleton of resting bovine platelets

Actin filaments in resting discoid bovine platelets were examined by fluorescence and electron microscopy. Rhodamine-phalloidin staining patterns showed a characteristic wheel-like structure which consisted of a central small circle connected by several radial spokes to a large peripheral circle. This wheel-like structure was composed of actin filaments forming a characteristic arrowhead structure with heavy meromyosin from muscle. Actin filaments were densely arrayed in parallel with a marginal microtubule band and radiated out from the center to the periphery. Platelets treated with colchicine lost their marginal microtubule band but retained their wheel-like structure and normal discoid form. Cytochalasin B disrupted the wheel-like structure but not the marginal microtubule band or the normal discoid form. After simultaneous treatment with both cytochalasin B and colchicine, platelets lost their discoid shape. These results suggest that actin filaments and microtubules both play important roles in the maintenance of the discoid shape of resting bovine platelets.     

Cytochalasin separates microtubule disassembly from loss of asymmetric morphology

When neuroblastoma cells bearing neurites are incubated with colchicine or Nocodazole, the cytoplasmic microtubules are depolymerized and concomitantly the neurites retract. We report here that cytochalasin separates the two effects of these drugs: it quantitatively inhibits neurite retraction but does not inhibit microtubule assembly. The neurites that remain contain intermediate filaments and actin but are devoid of microtubules. Depletion of cellular ATP also blocks neurite retraction induced by colchicine or Nocodazole, but some assembled microtubules persist under these conditions. The results suggest that neurite retraction is an active cell process.     

Role of microtubules in milk secretion — Action of colchicine on microtubules and exocytosis of secretory vesicles in rat mammary epithelial cells

Summary Effect of colchicine on microtubules was studied in mammary epithelial cells treated both in vivo and in vitro with the alkaloid. Three hours after the intramammary infusion of colchicine, secretory activity of mammary epithelia ceased, milk constituents accumulated and were randomly distributed within the cytoplasm, sometimes leaking into the perialveolar connective tissue, and autophagic vacuoles were prevalent. It appeared that an accelerated involutionary process was occurring. No microtubules were observed after this treatment. In vitro treated cells appeared to be less affected by the alkaloid. Although numerous casein-containing secretory vesicles accumulated in the cytoplasm, lipid droplet accumulation was less, and fewer autophagic vacuoles were observed, although lysosomes were commonly observed. Occasionally, obliquely sectioned microtubules were found in cells treated with low concentrations of colchicine but were absent at higher colchicine concentrations; however, paracrystalline inclusions (tubulin aggregates) were observed in some cells at all concentrations of the drug. These observations provide evidence that drugs which interfere with microtubule integrity reduce the secretory activity in mammary epithelia. This evidence is consistent with the concept of an association of the microtubular system and the secretory process.     

The effects of cytochalasin B and colchicine on the morphogenesis of mitochondria in Drosophila hydei during meiosis and early spermiogenesis

Summary Morphogenesis of mitochondria in male germ cells in cultivated cytocysts begins in early prophase I at which time mitochondria thicken and become ordered along the spindle apparatus during meiosis. At the end of the second meiotic division they aggregate to form the Nebenkern.In the presence of colchicine or cytochalasin B mitochondria are able to begin differentiation, although the correct course of meiosis is not guaranteed. In medium supplemented with colchicine they undergo normal thickening but do not aggregate, in a pattern known from untreated cultures. This may indicate that microtubules are involved in the aggregation process of mitochondria as colchicine is known to inhibit microtubule formation. Moreover, in cell cultures treated with cytochalasin B mitochondrial aggregation does occur; it is concluded that microfilaments, which are sensitive to cytochalasin B, do not play a detectable role in the aggregation of mitochondria.     

Ultrastructural effects of colchicine on perikarya and initial segment of rat retinal ganglion cells.

Our ultrastructural study was focused on the perikaryal region and initial segment of the axon of rat retinal ganglion cells in controls and after intraocular injections of colchicine. In control rats that region contained, among other organelles, elements of the Golgi complex and, close to them, short isolated microtubules oriented preferentially toward the axon where they funnel and aggregate in bundles. One day after sufficient doses of colchicine to inhibit axoplasmic transport (2-20 micrograms) these cytoplasmic microtubules were absent, whereas some axonal microtubules were still present but reduced in number. In addition, colchicine induced an altered distribution of organelles, leaving empty spaces in the periphery and most organelles concentrated in the perinuclear region, especially around Golgi elements where numerous vesicles and tubules accumulate at the trans face of Golgi elements. These results suggest that the vesicles that leave the Golgi and have been directed towards axoplasmic transport may need the cytoplasmic microtubules located between Golgi elements and the axonal initial segments to reach the axon.     

Plasmodium gallinaceum: critical role for microtubules in the transformation of zygotes into Ookinetes

The role of microtubules and microfilaments in the transformation of spherical zygotes of Plasmodium gallinaceum (avian malaria parasite) into vermiform ookinetes has been studied by using specific drugs (taxol, colchicine, and cytochalasin-B). Both taxol and colchicine completely abolished the transformation of zygotes into ookinetes. The inhibitory effect was seen only if the drugs were added during the initial 6 hr of total time (20-24 hr) required for complete transformation; the addition of drugs after 6-8 hr of initiation of transformation had no effect. Electron microscopy revealed that microtubules were depolymerized by colchicine treatment, whereas in taxol-treated cells there was an extensive array of cytoplasmic and nuclear microtubules which appeared to be clumped in bundles. In contrast to the effects of taxol and colchicine, cytochalasin-B, which affects the microfilament system, had no effect on the transformation. Protein synthesis and expression of two ookinete-specific surface proteins were not affected in the drug-inhibited parasites. Zygotes treated with taxol for 4 hr at room temperature failed to develop into oocysts when they were subsequently fed to mosquitoes. These studies demonstrate a critical role for microtubules in the initial stages of transformation of zygotes into ookinetes.